4022 composition of starting material) indicates that under these conditions ca. 94 =k 3 % of 2 is formed via a [4 21 cycloaddition. The position of the label in tricyclic product after heating 6 under a variety of conditions was determined using dmr spectroscopy. 1 2 , 1 3 The results based on the intensity ratio Df:Dex,1OO:O (184", 21 hr), 93:7 (193", 33.5 hr), and 70:30 (203", 36.5 hr)14 indicate that at 184" (21 hr) the formation of 2 proceeds exclusively by a [4 21 mechanism, but at higher temperatures at least one other pathway intervenes to scramble the label. Assuming that no more than 1 % of 2b is 21 pathway is kinetically formed at 184", the [4 favored by at least - R T In kz/kl = 4.576 (457.2) log (99) = -4.1 kcal/mol.'j Although the lower energy pathway to 2 must involve 21 cycloaddition of 1, several interpretations of a [4 the scrambling of the label between He,-He, and H r H , proton pairs are possible. Extensive commentary on the scrambling must await the full paper but suffice it to say that the raw kinetic data can encompass a diradical mechanism for this process involving the formation of 7 from 1 (or 2) followed by rapid coupling to give tricyclic product. l7 Studies are continuing to test for the involvement of a ,2&]cycloaddition in the primary formation of 2 [,4, and to obtain precise activation parameters for the reactions in this system. Acknowledgment. Acknowledgment is made to the Research Foundation and the Graduate School of the State University of New York at Stony Brook, to the Research Corporation, and to the donors of the Petroleum Research Fund, administered by the American Chemical Society, for support of this research.
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(12) D m r spectra were taken on a Bruker HFX-90 nmr spectrometer with a measuring frequency of 13.82 MHz by Mr. W. Schittenhelm of Bruker Scientific Inc., Elmsford, N. Y., t o whom I am indebted. Integrations were performed electronically with the aid of a Fabri-Tek 1080 computer. (13) The D, and De, resonances coincided in the 13.82-MHz dmr spectra but their combined intensities always equalled the sum of the intensities of the resolved Df and De, signals. No other signals were detectable in the dmr spectra of cyclized 6 . (14) After heating 6 for 36.5 hr a t 203", recovered dideuterio-5allylcyclohexa-1,3-dienecontained 1 4 Z of the label in the y position of the allyl side chain. (15! Since factors which stabilize products may be important in stabilizing the activated complex leading to products, the [2 21 reaction which produces cyclobutanes is usually disadvantaged compared to 41 case and the usual reaction course favoring formation of the [2 cyclohexenes can be explained without regard to the theory of Woodward and Hoffmann.16 However, the present result makes clear that even in a competition where the same product could have been formed 21 cycloaddition is still kinetically favored. from either pathway the [4 (16) R . B. Woodward and R. Hoffmann, Angew. Chem., Int. Ed. Engl., 8,781 (1969). (17) The experimentally derived value for the initial rate of formation 21 cycloaddition) at 193" is k = 6.16 X of 2 (due primarily to a [4 lo-' sec-1. The computed value of 39.4 i 3 kcal/molL* for the activation energy of formation of 2 from 1 coupled with an A factor estimatedls at 10ll.j * 0.6 gives k = 10-7 sec-1 for the slower diradical mechanism. (18) These parameters were estimated by group additivity methods described by (a) S . W. Benson in "Thermochemical Kinetics," Wiley, New York, N. Y., 1968; (b) S . W. Benson and H . E. O'Neal in "Kinetic Data on Gas Phase Unimolecular Reactions," NSRDS-NBS-21, 1970, U. S . Government Printing Offce, Washington, D. C.; (c) H. M. Frey and R. Walsh, Chem. Reo., 69, 103 (1969), and will be discussed in detail in the full paper.
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A. Krantz Department of Chemistry State Unicersity of New York at Stony Brook Stony Brook, New York I1790 Receiced February 15, 1972
Journal of tlze American Chemical Society
1
94:ll
1
A Simple Method for Assigning Vibrational Frequencies to Rapidly Equilibrating Rotational Isomers Sir: Continuing interest in the conformations of organic molecules and related spectral properties prompts us to report a novel and simple method based upon the matrix isolation technique for assigning vibrational frequencies to rapidly equilibrating rotational isomers. Previous workers have employed temperature-dependent infrared spectroscopic studies of gaseous and liquid samples, Raman spectroscopy, and infrared studies of the in the determination of vibrational patterns of individual conformers. In our method an immobilized mixture of conformers in an argon matrix at 20.4"K is prepared by rapid freezing of a room temperature equilibrated gas-phase sample. The conformer ratio is then perturbed by photochemical irradiation. Under the conditions of the experiment infrared bands are highly resolved, and the low temperature and rigidity of the matrix prohibit thermal interconversion of conformers corresponding to local energy minima.5 If the conformer ratio is displaced photochemically, analysis of the changes in the relative intensities of bands allows assignments to be made to the components of the mixture. The method is illustrated for but-3-en-2-one (1) which has been studied spectroscopically and is thought to exist primarily in the s-cis and s-trans forms.2,6-8 The enthalpy difference between the two rotamers is approximately 0.5 kcal/mol favoring the s-trans form. i -0
R
0 s-cis
s-trans 1, R = CH,
2,R=H
Photoirradiation of 1 in an Ar matrix(M/R = 800) with nickel sulfate filtered light from a medium pressure mercury arc for periods up to 4.16 hr produced only changes in the relative intensities of bands as shown for a representative region of the infrared spectrum in Figure 1. A number of bands which included the carbonyl absorption at 1690 cm- l previously assigned to the s-trans conformer upon irradiation decreased at identical rates, whereas another set showed a corresponding increase in intensity. The observation of a reciprocal relationship between two sets of bands (1) (a) N. Oi and J. F. Coetzee, J . Amer. Chem. Soc., 91, 2473, 2478 (1969); (b) G. J. Karabatsos and D. J. Fenoglio, ibid.,91, 1124, 3572, 3577 (1969); (c) A . J. Bowles, W. 0. George, and D. B. CunliffeJones, Chem. Commun., 103 (1970); (d) W. E. Stewart and T. H . Siddall, 111, Chem. Reo., 70, 517(1970); ( e ) D . J. Chadwick, J. Chambers, G. D. Meakins, and R . L. Snowden, Chem. Commun., 624, 625 (1971); (f) I. Juchnovski and J. Kaneti, Tetrahedron, 27, 4269 (1971); (g) D. D. Faulk and A. Fry, J. Org. Chem., 35, 364 (1970); (h) R . B. Birge, W. C. Pringle, and P. A . Leermakers, J . Amer. Chem. Soc., 93, 6715 (1971). f2) I